1 / 60

Chapter 2

Chapter 2. Descriptive Statistics: Tabular and Graphical Methods. Descriptive Statistics. 2.1 Graphically Summarizing Qualitative Data 2.2 Graphically Summarizing Quantitative Data 2.3 Dot Plots 2.4 Stem-and-Leaf Displays 2.5 Crosstabulation Tables ( Optional ).

rachael
Download Presentation

Chapter 2

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Chapter 2 Descriptive Statistics: Tabular and Graphical Methods

  2. Descriptive Statistics 2.1 Graphically Summarizing Qualitative Data 2.2 Graphically Summarizing Quantitative Data 2.3 Dot Plots 2.4 Stem-and-Leaf Displays 2.5 Crosstabulation Tables (Optional)

  3. Descriptive Statistics Continued 2.6 Scatter Plots (Optional) 2.7 Misleading Graphs and Charts (Optional)

  4. Graphically Summarizing Qualitative Data • With qualitative data, names identify the different categories • This data can be summarized using a frequency distribution • Frequency distribution: A table that summarizes the number of items in each of several non-overlapping classes.

  5. Example 2.1: Describing 2006 Jeep Purchasing Patterns • Table 2.1 lists all 251 vehicles sold in 2006 by the greater Cincinnati Jeep dealers • Table 2.1 does not reveal much useful information • A frequency distribution is a useful summary • Simply count the number of times each model appears in Table 2.1

  6. The Resulting Frequency Distribution

  7. Relative Frequency and Percent Frequency • Relative frequency summarizes the proportion of items in each class • For each class, divide the frequency of the class by the total number of observations • Multiply times 100 to obtain the percent frequency

  8. The Resulting Relative Frequency and Percent Frequency Distribution

  9. Bar Charts and Pie Charts • Bar chart: A vertical or horizontal rectangle represents the frequency for each category • Height can be frequency, relative frequency, or percent frequency • Pie chart: A circle divided into slices where the size of each slice represents its relative frequency or percent frequency

  10. Excel Bar Chart of the Jeep Sales Data

  11. Excel Pie Chart of the Jeep Sales Data

  12. Pareto Chart • Pareto chart: A bar chart having the different kinds of defects listed on the horizontal scale • Bar height represents the frequency of occurrence • Bars are arranged in decreasing height from left to right • Sometimes augmented by plotting a cumulative percentage point for each bar

  13. Excel Frequency Table and Pareto Chart of Labeling Defects

  14. Graphically Summarizing Qualitative Data • Often need to summarize and describe the shape of the distribution • One way is to group the measurements into classes of a frequency distribution and then displaying the data in the form of a histogram

  15. Frequency Distribution • A frequency distribution is a list of data classes with the count of values that belong to each class • “Classify and count” • The frequency distribution is a table • Show the frequency distribution in a histogram • The histogram is a picture of the frequency distribution

  16. Constructing a Frequency Distribution Steps in making a frequency distribution: • Find the number of classes • Find the class length • Form non-overlapping classes of equal width • Tally and count • Graph the histogram

  17. Example 2.2 The Payment Time Case: A Sample of Payment Times Table 2.4

  18. Number of Classes • Group all of the n data into K number of classes • K is the smallest whole number for which 2K n • In Examples 2.2 n = 65 • For K = 6, 26 = 64, < n • For K = 7, 27 = 128, > n • So use K = 7 classes

  19. Number of Classes In General

  20. Class Length • Find the length of each class as the largest measurement minus the smallest divided by the number of classes found earlier (K) • For Example 2.2, (29-10)/7=2.7143 • Because payments measured in days, round to three days

  21. Form Non-Overlapping Classes of Equal Width • The classes start on the smallest value • This is the lower limit of the first class • The upper limit of the first class is smallest value + class length • In the example, the first class starts at 10 days and goes up to 13 days • The next class starts at this upper limit and goes up by class length • And so on

  22. Seven Non-Overlapping Classes Payment Time Example

  23. Tally and Count the Number of Measurements in Each Class

  24. Histogram • Rectangles represent the classes • The base represents the class length • The height represents • the frequency in a frequency histogram, or • the relative frequency in a relative frequency histogram

  25. Histograms Frequency Histogram Relative Frequency Histogram

  26. Some Common Distribution Shapes • Skewed to the right: The right tail of the histogram is longer than the left tail • Skewed to the left: The left tail of the histogram is longer than the right tail • Symmetrical: The right and left tails of the histogram appear to be mirror images of each other

  27. A Right-Skewed Distribution

  28. A Left-Skewed Distribution

  29. Frequency Polygons • Plot a point above each class midpoint at a height equal to the frequency of the class • Useful when comparing two or more distributions

  30. Example 2.3: Comparing The Grade Distribution for Two Statistics Exams • Table 2.8 (in textbook) gives scores earned by 40 students on first statistics exam • Table 2.9 gives the scores on the second exam after an attendance policy • Due to the way exams are reported, used the classes: 30<40, 40<50, 50<60, 60<70, 70<80, 80<90, and 90<100

  31. A Percent Frequency Polygon of the Exam Scores

  32. A Percent Frequency Polygon Comparing the Two Exam Scores

  33. Cumulative Distributions • Another way to summarize a distribution is to construct a cumulative distribution • To do this, use the same number of classes, class lengths, and class boundaries used for the frequency distribution • Rather than a count, we record the number of measurements that are less than the upper boundary of that class • In other words, a running total

  34. Frequency, Cumulative Frequency, and Cumulative Relative Frequency Distribution

  35. Ogive • Ogive: A graph of a cumulative distribution • Plot a point above each upper class boundary at height of cumulative frequency • Connect points with line segments • Can also be drawn using • Cumulative relative frequencies • Cumulative percent frequencies

  36. A Percent Frequency Ogive of the Payment Times

  37. Dot Plots • On a number line, each data value is represented by a dot placed above the corresponding scale value • Dot plots are useful for detecting outliers • Unusually large or small observations that are well separated from the remaining observations

  38. Dot Plots Example

  39. Stem-and-Leaf Display • Purpose is to see the overall pattern of the data, by grouping the data into classes • the variation from class to class • the amount of data in each class • the distribution of the data within each class • Best for small to moderately sized data distributions

  40. Car Mileage Example 29 + 0.8 = 29.8 33 + 0.3 = 33.3 • Refer to the Car Mileage Case • Data in Table 2.14 • The stem-and-leaf display: 29 8 30 13455677888 31 0012334444455667778899 32 01112334455778 33 03

  41. Car Mileage: Results • Looking at the stem-and-leaf display, the distribution appears almost “symmetrical” • The upper portion (29, 30, 31) is almost a mirror image of the lower portion of the display (31, 32, 33) • Stems 31, 32*, 32, and 33* • But not exactly a mirror reflection

  42. Constructing a Stem-and-Leaf Display • There are no rules that dictate the number of stem values • Can split the stems as needed

  43. Split Stems from Car Mileage Example • Starred classes (*) extend from 0.0 to 0.4 • Unstarred classes extend from 0.5 to 09 29 8 30* 134 30 55677888 31* 00123344444 31 55667778899 32* 011123344 32 55778 33* 03

  44. Comparing Two Distributions • To compare two distributions, can construct a back-to-back stem-and-leaf display • Uses the same stems for both • One leaf is shown on the left side and the other on the right

  45. Sample Back-to-Back Stem-and-Leaf Display

  46. Crosstabulation Tables (Optional) • Classifies data on two dimensions • Rows classify according to one dimension • Columns classify according to a second dimension • Requires three variable • The row variable • The column variable • The variable counted in the cells

  47. Example 2.5: The Investor Satisfaction Case • Investment broker sells several kinds of investments • A stock fund • A bond fund • A tax-deferred annuity • Wishes to study whether satisfaction depends on the type of investment product purchased

  48. Bond Fund Satisfaction Survey Data in Table 2.16

  49. More on Crosstabulation Tables • Row totals provide a frequency distribution for the different fund types • Column totals provide a frequency distribution for the different satisfaction levels • Main purpose is to investigate possible relationships between variables

  50. Percentages • One way to investigate relationships is to compute row and column percentages • Compute row percentages by dividing each cell’s frequency by its row total and expressing as a percentage • Compute column percentages by dividing by the column total

More Related